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Effect of experimental, morphological and mechanical factors on the murine spinal cord subjected to transverse contusion: A finite element study

Marion Fournely, Yvan Petit, Éric Wagnac, Morgane Evin, Pierre‐Jean Arnoux

2020PLoS ONE25 citationsDOIOpen Access PDF

Abstract

Finite element models combined with animal experimental models of spinal cord injury provides the opportunity for investigating the effects of the injury mechanism on the neural tissue deformation and the resulting tissue damage. Thus, we developed a finite element model of the mouse cervical spinal cord in order to investigate the effect of morphological, experimental and mechanical factors on the spinal cord mechanical behavior subjected to transverse contusion. The overall mechanical behavior of the model was validated with experimental data of unilateral cervical contusion in mice. The effects of the spinal cord material properties, diameter and curvature, and of the impactor position and inclination on the strain distribution were investigated in 8 spinal cord anatomical regions of interest for 98 configurations of the model. Pareto analysis revealed that the material properties had a significant effect (p<0.01) for all regions of interest of the spinal cord and was the most influential factor for 7 out of 8 regions. This highlighted the need for comprehensive mechanical characterization of the gray and white matter in order to develop effective models capable of predicting tissue deformation during spinal cord injuries.

Topics & Concepts

Spinal cordSpinal cord injuryAnatomyFinite element methodBiomechanicsWhite matterMedicineMaterials scienceBiomedical engineeringStructural engineeringMagnetic resonance imagingPsychiatryRadiologyEngineeringSpinal Cord Injury ResearchAutomotive and Human Injury BiomechanicsTrauma Management and Diagnosis
Effect of experimental, morphological and mechanical factors on the murine spinal cord subjected to transverse contusion: A finite element study | Litcius